I am trying to understand how to manually calculate a confidence interval of a multiple linear regression(OLS). My problem is that I don't know how to calculate the standard error for all of the individual coefficients.
For a regression with just one independent variable, I followed to following tutorial: http://stattrek.com/regression/slope-confidence-interval.aspx. This tutorial provides the following formula:
As it turns out, the formula works. However, I did not fully understand the formula. For example, why is the (-2) at the top of the formula. To validate the correctness I wrote the following r code that already shows the standard errors:
x<-1:50
y<-c(x[1:48]+rnorm(48,0,5),rnorm(2,150,5))
QR <- rq(y~x, tau=0.5)
summary(QR, se='boot')
LM<-lm(y~x)
alligator = data.frame(
lnLength = c(3.78, 3.71, 3.73, 3.78),
lnWeight = c(4.43, 4.38, 4.42, 4.25)
)
alli.mod1 = lm(lnWeight ~ ., data = alligator)
newdata = data.frame(
lnLength = c(3.78, 3.71, 3.73, 3.78)
)
y_predicted = predict(alli.mod1, newdata, interval="predict")[,1]
length_mean = mean(alligator$lnLength)
> summary(alli.mod1)
Call:
lm(formula = lnWeight ~ ., data = alligator)
Residuals:
1 2 3 4
0.08526 -0.02368 0.03316 -0.09474
Coefficients:
Estimate Std. Error t value Pr(>|t|)
(Intercept) 7.5279 5.7561 1.308 0.321
lnLength -0.8421 1.5349 -0.549 0.638
Residual standard error: 0.09462 on 2 degrees of freedom
Multiple R-squared: 0.1308, Adjusted R-squared: -0.3038
F-statistic: 0.301 on 1 and 2 DF, p-value: 0.6383
Then I manually computed the SE using the following r code(According to the above formula):
rss = (alligator$lnWeight[1] - y_predicted[1])^2 +
(alligator$lnWeight[2] - y_predicted[2])^2 +
(alligator$lnWeight[3] - y_predicted[3])^2 +
(alligator$lnWeight[4] - y_predicted[4])^2
a = sqrt(rss/(length(y_predicted)-2))
b = sqrt((alligator$lnLength[1] - length_mean)^2 +
(alligator$lnLength[2] - length_mean)^2 +
(alligator$lnLength[3] - length_mean)^2 +
(alligator$lnLength[4] - length_mean)^2)
a/b
1.534912
Which resulted in the same value as the SE of summary(alli.mod1). So, I thought, maybe it works when I try it with 2 variables. Unfortunately, this resulted in an incorrect answer. As shown in the below code:
alligator = data.frame(
lnLength = c(3.78, 3.71, 3.73, 3.78),
lnColor = c(2.43, 2.59, 2.46, 2.22),
lnWeight = c(4.43, 4.38, 4.42, 4.25)
)
alli.mod1 = lm(lnWeight ~ ., data = alligator)
newdata = data.frame(
lnLength = c(3.78, 3.71, 3.73, 3.78),
lnColor = c(2.43, 2.59, 2.46, 2.22)
)
y_predicted = predict(alli.mod1, newdata, interval="predict")[,1]
length_mean = mean(alligator$lnLength)
color_mean = mean(alligator$lnColor)
rss = (alligator$lnWeight[1] - y_predicted[1])^2 +
(alligator$lnWeight[2] - y_predicted[2])^2 +
(alligator$lnWeight[3] - y_predicted[3])^2 +
(alligator$lnWeight[4] - y_predicted[4])^2
a = sqrt(rss/(length(y_predicted)-2))
b = sqrt((alligator$lnColor[1] - color_mean)^2 +
(alligator$lnColor[2] - color_mean)^2 +
(alligator$lnColor[3] - color_mean)^2 +
(alligator$lnColor[4] - color_mean)^2)
b1 = sqrt((alligator$lnLength[1] - length_mean)^2 +
(alligator$lnLength[2] - length_mean)^2 +
(alligator$lnLength[3] - length_mean)^2 +
(alligator$lnLength[4] - length_mean)^2)
> summary(alli.mod1)
Call:
lm(formula = lnWeight ~ ., data = alligator)
Residuals:
1 2 3 4
0.006725 -0.041534 0.058147 -0.023338
Coefficients:
Estimate Std. Error t value Pr(>|t|)
(Intercept) -3.5746 8.8650 -0.403 0.756
lnLength 1.6569 2.1006 0.789 0.575
lnColor 0.7140 0.4877 1.464 0.381
Residual standard error: 0.07547 on 1 degrees of freedom
Multiple R-squared: 0.7235, Adjusted R-squared: 0.1705
F-statistic: 1.308 on 2 and 1 DF, p-value: 0.5258
> a/b
1
0.2009918
> a/b1
1
0.8657274
Is there a general approach I could follow to compute the standard error?